JP2005050054A - Image input device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image input device capable of satisfying both reading of an image and performance of display. <P>SOLUTION: This image input device having an input/output integrated display 8 has an optical element 9. By sliding the optical element 9 along a groove 10a nearly parallel to the surface of the input/output integrated display 8, a state wherein the optical element 9 is placed on a display face 8a of the input/output integrated display 8 and a state wherein the optical element 9 is out of the display face 8a of the input/output integrated display 8 can be changed over. Accordingly, in the image input device, the optical element does not impair the display performance even when displaying the image, while improving blurring of the image when reading the image. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention includes an image sensor capable of reading an image of a document, and an optical element used for the purpose of limiting the spread of light of the read image and for increasing the depth of field at the time of image reading. The present invention relates to an image input device. In particular, according to the present invention, as the image sensor, an input / output integrated display capable of performing image display and document image reading on the same screen, and document image reading can be performed on the surface. The present invention relates to an image input device including an area sensor.
[0002]
[Prior art]
In recent years, electronic devices such as personal computers and PDAs (portable personal terminals) have become widespread, and the demand for reading various information into the electronic devices as electronic information is increasing. Therefore, a scanner is used as a means for reading information printed on paper or the like.
[0003]
However, these problems are that the scanner is isolated as a peripheral device, often hindering the carrying of the electronic device, and requires a space for installation, which causes a problem of the placement location.
[0004]
For this situation, a flat panel display used in electronic devices such as personal computers and PDAs incorporates a scanner function (that is, an image reading function) so that images can be displayed and read on the same screen. Output-integrated displays have been proposed.
[0005]
For example, an example of realizing a liquid crystal display integrated with input and output by providing both liquid crystal driving TFT (thin film transistor) elements and optical sensor elements in each pixel of the active matrix substrate constituting the liquid crystal display is patented. It is disclosed in Document 1 and Patent Document 2.
[0006]
On the other hand, an example of realizing an input / output integrated EL display by providing both an EL driving TFT element and an optical sensor element in each pixel of an active matrix substrate constituting an EL (electroluminescence) display, This is disclosed in Patent Document 3.
[0007]
In the input / output integrated display disclosed in Patent Documents 1 to 3, when an image is displayed, an image is displayed on a display surface (screen) like an ordinary liquid crystal display or EL display, and an observer (user) is displayed. Can obtain image information by looking at the screen. On the other hand, when reading an image, a document (printed material or the like) as a subject is brought into close contact with a screen used for display. A light source used for display (a backlight in the case of a liquid crystal display, an EL element in the case of an EL display) is used to irradiate a document placed on the screen, and the reflected light is built into the active matrix substrate. By detecting with an optical sensor, an image (optical information) of a document is read.
[0008]
However, in the case of the input / output integrated display disclosed in Patent Documents 1 to 3, the following problems occur.
[0009]
In general, many originals have information printed on paper such as newspapers, magazines, and printed matter printed on high-quality paper. Except for glossy paper such as gravure paper, the paper has scattering properties close to perfect diffusion. Therefore, when light from a light source is irradiated on a document placed on the display screen, the reflected light of the document having the above properties is scattered approximately isotropically.
[0010]
The above problem will be described with reference to FIG.
[0011]
As shown in FIG. 10A, if the optical sensors 104n-2 to 104n + 2 built in the active matrix substrate (photosensor substrate) 101 and the original 103 are close to each other, the reflected light of the original 103 will be reflected. Even if the light is scattered, the optical sensor 102 provided in a certain pixel 104n mainly receives light emitted from the position of the original 103 corresponding to the pixel 104n, and the read image is not blurred. However, as shown in FIG. 10B, as the distance (gap) L between the optical sensor 102 built in the active matrix substrate 101 and the original 103 increases, the optical sensor 102 provided in the pixel 104n is It becomes easy to receive obliquely reflected light emitted from the document 3 at a position corresponding to the pixel 104n-1 or the pixel 104n + 1 adjacent to the pixel 104n. That is, the crosstalk of the reflected light from the original 103 becomes intense. As a result, as the distance L is increased, the image is degraded such that the read image is blurred.
[0012]
In particular, in the case of the input / output integrated display as described above, the glass constituting the display panel is provided between the surface of the active matrix substrate 101 on which the optical sensor 102 is formed and the surface of the screen (not shown) on which the document 103 is closely attached. Since the substrate and the polarizing plate (not shown) exist, the gap L is inevitably increased. For this reason, it is difficult to avoid the problem of image deterioration such that the read image is blurred.
[0013]
Therefore, in order to solve the above-described problem, Patent Document 4 discloses a technique in which a fiber plate having a light shielding layer is further provided between the screen surface of the display and the original. The fiber plate is a general term for a glass fiber plate and an optical fiber plate, and is provided with a plurality of glass fibers or optical fibers each composed of a light absorption layer and a light transmission layer. By using the fiber plate, the reflected light in the oblique direction emitted from the document is cut, and only effective reflected light is transmitted through the fiber plate to reach a predetermined optical sensor.
[0014]
Further, in Patent Document 1, a hemispherical or rod-shaped microlens focused on the photosensor of each pixel is provided on the upper side of the polarizing plate or the polarizing plate in order to ensure a sufficient amount of light incident on the photosensor from the document surface. It is also disclosed that it is formed between the substrate and the counter substrate (see paragraphs [0022] and [0023] of Patent Document 1).
[0015]
In Patent Document 2, an optical fiber plate is provided between the polarizing plate and the counter substrate so that more light can be used, and the light from the original can be imaged on the sensor to further reduce the reading error. It is also disclosed that a lens array sheet is provided between the polarizing plate and the counter substrate so as to be able to perform (see paragraph [0064] of Patent Document 2).
[0016]
[Patent Document 1]
Japanese Patent Laid-Open No. 5-121715 (published May 18, 1993)
[0017]
[Patent Document 2]
JP 2001-109394 A (published on April 20, 2001)
[0018]
[Patent Document 3]
JP 2002-176162 A (released on June 21, 2002)
[0019]
[Patent Document 4]
JP 2002-251164 A (published on September 6, 2002)
[0020]
[Problems to be solved by the invention]
However, the structure provided with the above-described fiber plate, hemispherical or rod-shaped microlens, and lens array sheet can solve the problem of image blur at the time of image reading, the fiber plate at the time of display, This is accompanied by display performance caused by a hemispherical or rod-shaped microlens or lens array sheet. This is because an observer (user) observes an image through a fiber plate, a hemispherical or rod-shaped microlens, and a lens array sheet installed on the screen.
[0021]
Since the fiber plate transmits only light within a predetermined aperture angle (NA), the oblique component of the display light emitted from the display panel is reflected and absorbed by the fiber plate. As a result, there arises a problem that the viewing angle is always very narrow in display and the luminance is lowered.
[0022]
In addition, hemispherical or rod-shaped microlenses and lens array sheets limit the viewing angle and degrade the display performance.
[0023]
In addition, the structure provided with the fiber plate, the hemispherical or rod-shaped microlens, and the lens array sheet as described above can solve the problem of image blur at the time of image reading, and the brightness at the time of image reading. That will reduce it somewhat. This is because the reflected light from the original enters the sensor via the fiber plate, hemispherical or rod-shaped microlens, and lens array sheet. When the brightness at the time of image reading decreases, it becomes difficult to read at high speed.
[0024]
Since the fiber plate transmits only light within a predetermined aperture angle (NA), the oblique component of the display light emitted from the display panel is reflected and absorbed by the fiber plate. As a result, there arises a problem that the viewing angle is always very narrow in display and the luminance is lowered.
[0025]
In addition, hemispherical or rod-shaped microlenses and lens array sheets limit the viewing angle and degrade the display performance.
[0026]
The present invention has been made in view of the above problems, and an object of the present invention is to provide an input / output integrated image input apparatus that can satisfy both image reading and display performance. It is in.
[0027]
Another object of the present invention is to provide an image input apparatus that can selectively use a mode in which a read image without blur is obtained and a mode in which an image can be read at high speed.
[0028]
[Means for Solving the Problems]
In order to solve the above-described problems, an image input device according to the present invention includes an input / output integrated display capable of displaying an image and reading an image of a subject on the same screen, and the light of the read image. An optical element for limiting the spread, and switching means for switching the optical element between an installation state installed on the screen and a non-installation state removed from the screen Yes.
[0029]
As described above, when a document such as paper having scattering characteristics close to perfect diffusion is placed on the screen and an image of the document such as paper is read, when the light from the input / output integrated display is irradiated to the document, The reflected light of the original is scattered isotropically, and the read image is blurred. Therefore, in order to obtain a read image without blur, it is necessary to install an optical element that restricts the spread of light in the read image. However, as described above, according to the conventional technology, the optical element cannot be removed from the screen. Therefore, when the image is displayed, the optical element limits the viewing angle, and the display performance is reduced. It will decrease.
[0030]
However, according to the configuration of the present invention, since the optical element is provided with a switching means for switching between the installation state installed on the screen and the non-installation state removed from the screen, for example, These states can be arbitrarily switched by a user operation. Therefore, it is possible to install an optical element on the screen only when reading an image of a document, and to remove the optical element from the screen when displaying an image.
[0031]
Accordingly, it is possible to avoid blurring of an image when reading an image of a document by installing an optical element, and to prevent a viewing angle from being limited by the optical element when displaying an image. In other words, it is possible to realize an image input device that can achieve both improvement in reading performance of an image of a document and display of a wide viewing angle.
[0032]
The image input apparatus according to the present invention is an optical device that causes the optical element to act as an optical element that restricts the spread of light of a read image when reading, and that restricts a viewing angle when displaying an image. It can also be used in a usage method that acts as an element. Since the optical element limits the viewing angle, it is possible to remove the optical element from the screen when a wide viewing angle is required for display. If the user does not want to limit the viewing angle, that is, the viewing angle is limited, the viewing angle can be controlled by installing the optical element on the screen.
[0033]
In the present specification, “the optical element is placed on the screen” means that at least a part of the optical element is placed between the screen and the viewpoint position at which the display of the screen looks normal. Shall point to. Further, “the optical element is removed from the screen” means that the entire optical element is installed at a position that does not intervene between the viewpoint position at which the display of the screen can be normally viewed and the screen.
[0034]
In the present specification, “original” refers to an object (subject) to be read, and includes not only a planar object such as a printed matter, a photograph, and a picture, but also a three-dimensional object.
[0035]
The optical element for limiting the spread of light of the read image is preferably an erecting equal-magnification lens array composed of a plurality of lenses.
[0036]
The erecting equal-magnification lens array can limit brightness, viewing angle, depth of field, and the like, and can relay an erect image of an original to the imaging surface. Therefore, it is possible to read an image of a document placed at a position having a predetermined interval from the imaging surface (image input device surface). In addition, since it is possible to adjust the depth of field depending on the design of the light receiving angle of the erecting equal-magnification lens, it is easy to eliminate blurring of the image.
[0037]
The image input device of the present invention may further include a light source for irradiating light on the document when reading an image, and the light source may be fixed so as to be integrated with the optical element.
[0038]
As a result, when the image is read, the light source can be arranged on the screen so that the light from the light source can be irradiated onto the document, and when the image is displayed, the light source can be removed from the screen. Therefore, the original can be efficiently irradiated with light, and the display performance is not impaired by the light source when an image is displayed. Further, since the switching of the optical element state and the switching of the light source state can be performed only by the operation of switching the optical element state, it is possible to realize an easy-to-use image input device without requiring a troublesome operation of the user. It becomes possible.
[0039]
The image input apparatus of the present invention includes a light source for irradiating light on a document when reading an image, an installation state in which the light source is installed on the screen, and a non-installation state in which the light source is removed from the screen. And a light source switching means for switching between them.
[0040]
As a result, when the image is read, the light source can be arranged on the screen so that the light from the light source can be irradiated onto the document, and when the image is displayed, the light source can be removed from the screen. Therefore, the original can be efficiently irradiated with light, and the display performance is not impaired by the light source when an image is displayed. In addition, since it is possible to switch the state of the light source independently of the switching of the state of the optical element, only the light source is withdrawn from the screen at the time of display, and the optical element is used on the screen. It becomes possible. That is, the optical element can act as an optical element that limits the spread of the light of the read image when reading, and can act as an optical element that limits the viewing angle when displaying an image. Become.
[0041]
As a result, when a display with a wide viewing angle is required at the time of display, the above-mentioned optical element is removed from the screen, and conversely, if you do not want to look into the screen from the next person, that is, if you want to limit the viewing angle, By installing the optical element on the screen, the viewing angle can be changed.
[0042]
The image input apparatus of the present invention further includes mode switching means for switching between a reading mode for reading an image of a document and a display mode for displaying an image, and the mode switching means includes the optical element in an installed state and a non-installed state. The mode may be switched in conjunction with the change between the states.
[0043]
As a result, the switching of the optical element state and the mode switching can be performed only by the operation of switching the state of the optical element, so that an easy-to-use image input device is realized without requiring troublesome operations of the user. It becomes possible.
[0044]
The switching means may be an attachment mechanism that allows the optical element to be attached to the image input apparatus main body only when necessary, but the optical element can reciprocate between a position on the screen and a position outside the screen. It is more preferable to include an optical element moving mechanism for supporting the optical element. As a result, as in the attachment mechanism, the user can take out the optical element placed at another place and switch the optical element to the image input device main body for switching the optical element, or the user can attach the optical element to the image input device main body. There is no need to remove the optical element from the lens and place it elsewhere. Therefore, the user can easily switch the optical element.
[0045]
In the image input device of the present invention, the switching means includes a slide mechanism that supports the optical element so that the optical element can slide on the screen and reciprocate between a position on the screen and a position outside the screen. It is characterized by including.
[0046]
Thereby, the optical element can be switched between an installed state and a non-installed state with a simple configuration.
[0047]
As described above, the optical element moving mechanism is preferably a slide mechanism, but is not limited to this. For example, the optical element rotates about a rotation axis substantially parallel to the screen. May be a rotation mechanism that supports the optical element so as to reciprocate between a position on the screen and a position outside the screen.
[0048]
The image input apparatus of the present invention may further include display moving means for moving the display so as to approach the observer's viewpoint in response to a state change from the installation state of the optical element to the non-installation state. .
[0049]
Accordingly, when the optical element is removed from the screen and placed in a non-installed state, it is possible to eliminate the user's uncomfortable feeling due to the screen being positioned on the back side from the surface of the image input device.
[0050]
The image input apparatus of the present invention further includes a lid (lid mechanism) for covering the screen, the optical element is built in the lid, and the switching unit is configured to install the lid on the screen. The configuration may be lid switching means for switching between the installed state and the non-installed state removed from the screen.
[0051]
Accordingly, by incorporating the optical element into a cover that is usually provided to protect the screen of the image input apparatus, a special space for incorporating the optical element on the main body side is not required, which is useful. In addition, the reading mode can be used when the cover is put on the screen, and the display mode can be used when the cover is removed. In other words, since the switching of the optical element state and the opening and closing of the lid can be performed only by the opening and closing operation of the lid, it is possible to realize an easy-to-use image input device without requiring troublesome operations by the user. Become.
[0052]
In the image input device of the present invention, the optical element is provided in an opening of the housing, and the lid surface of the portion where the optical element is installed is substantially flush with the surface of the housing. A configuration in which a light-transmitting spacer is provided on the optical element may be employed.
[0053]
As a result, the lid surface becomes flat, and it is possible to obtain a good read image by flattening the document surface by simply bringing the document into close contact with the lid surface. In addition, since there is no unevenness on the surface of the lid, it is possible to smoothly put in and out even when the image input device is not used and it is stored in a pocket of clothes.
[0054]
Here, “to be substantially flush” is a concept including a case where the surface is completely flat and a case where there is a slight unevenness but the surface is substantially flat. Moreover, the surface being substantially flat means a state where it can be seen as a flat surface when observed by human eyes.
[0055]
In the image input apparatus of the present invention, the optical element is provided in an opening of the casing, and the thickness of the casing is set to be thicker than the thickness of the optical element by a thickness corresponding to the focal length of the optical element. It is preferable.
[0056]
Accordingly, the focal point of the optical system can be made coincident with the surface of the document simply by bringing the document into close contact with the surface of the lid, so that it is easy to use.
[0057]
The image input apparatus according to the present invention includes an area sensor that can read an image of a document on a surface, and an image sensor when the image is read when compared with a case where the image sensor is installed on the surface. An optical element for increasing the depth of field; a switching means for switching the optical element between an installation state installed on the surface and a non-installation state removed from the surface; and an image reading speed. And a reading speed control means for changing, wherein the reading speed control means changes the image reading speed so that the non-installation state is faster than the installation state.
[0058]
This makes it possible to selectively use speed-priority reading and depth-of-field priority reading depending on the application and purpose. In other words, it is possible to provide an image input apparatus that can selectively use a mode in which a read image without blur is obtained and a mode in which an image can be read at high speed.
[0059]
In the above configuration, an image can be read in either case where the optical element is installed on the area sensor or in a form where the optical element is not installed on the area sensor.
[0060]
Here, the area sensor is also called a surface sensor, and is an image sensor that can read an image on a surface by a plurality of two-dimensionally arranged optical sensors.
[0061]
The area sensor may be incorporated in a screen capable of displaying an image, and the image may be displayed and read on the same screen. In other words, the area sensor may be an input / output integrated display capable of performing image display and document image reading on the same screen.
[0062]
As a result, the optical element can be used as a means for selectively using a display with priority on brightness and a display with priority on viewing angle restriction depending on the application and purpose. That is, it is possible to provide an input / output integrated image input apparatus that can selectively use display with priority on brightness and display with priority on viewing angle restriction.
[0063]
The optical element that increases the depth of field at the time of image reading when installed on the above surface compared to when removed from the above surface is an erecting equal-magnification lens array composed of a plurality of lenses. Preferably there is.
[0064]
The erecting equal-magnification lens array can limit brightness, viewing angle, depth of field, and the like, and can relay an erect image of a document to the imaging surface.
[0065]
From this, by switching the installation or non-installation of the erecting equal-magnification lens array on the area sensor as described above, speed-priority reading and depth-of-field priority are selected according to the application and purpose. Reading can be used properly, and the erecting equal-magnification lens array can also be used as means for selectively using brightness priority display and viewing angle restriction priority display according to the application and purpose.
[0066]
The image input device of the present invention preferably further includes a light shielding wall formed in a gap between the lenses constituting the erecting equal-magnification lens array.
[0067]
The erecting equal-magnification lens array can restrict the spread of light of the read image, but unnecessary oblique light is generated from the gap between the lenses of the erecting equal-magnification lens.
[0068]
However, according to the above configuration, since the light shielding wall is formed in the gap between the lenses, the unnecessary oblique light can be blocked. as a result,
[0069]
DETAILED DESCRIPTION OF THE INVENTION
[Embodiment 1]
An embodiment of the image input apparatus according to the present invention will be described below with reference to FIGS.
[0070]
FIG. 1 shows a portable image input device as a typical embodiment.
[0071]
The image input device includes a housing (image input device main body) 7 and an input / output integrated display 8 provided in the housing 7, and exposes a display surface 8 a of the input / output integrated display 8. As described above, the housing 7 is provided with an opening corresponding to the display surface 8a.
[0072]
The input / output integrated display 8 is a display capable of displaying an image and reading an image of a document as a subject on the same display surface (screen) 8a. That is, the input / output integrated display 8 is two-dimensionally arranged inside the display panel with respect to a display-only light-emitting display (a liquid crystal display having a light source, an EL display, etc.) composed of a display panel or the like. In addition, this is a display in which a plurality of optical sensors 2 are incorporated so that an image of a document can be read on the display surface (screen) of the display.
[0073]
The image input device is characterized in that an optical element 9 for limiting the spread of the light of the read image is provided on the outside (observer side) of the display surface (also serving as the imaging surface) 8a of the input / output integrated display 8. The optical element 9 is removable from the display surface 8a, that is, can be switched between an installation state installed on the display surface 8a and a non-installation state removed from the display surface 8a. It is a point.
[0074]
FIG. 1A is a diagram showing a non-installation state (optical device non-installation state) in which the optical element 9 is removed from the display surface 8a of the input / output integrated display 8, and FIG. 9 is a diagram showing an installation state (optical element installation state) in which 9 is installed on the display surface 8a of the input / output integrated display 8. FIG. In addition,
The main purpose of installing the optical element 9 on the display surface 8a is to limit the light spread of the read image when the image of the original is read by taking an image with the input / output integrated display 8, that is, the image pickup surface (display surface). This is because the light incident on 8a) is reduced (that is, the oblique incident component is limited).
[0075]
As a result, even if the document as the subject is a document such as paper having perfect diffusion characteristics, the light passing through the optical element 9 is limited to the light within the opening angle of the optical element 9, so that the read image is Image degradation such as blurring can be reduced. That is, by installing the optical element 9 on the display surface 8a, the depth of field is larger than the case where the optical element 9 is not installed on the display surface 8a (the depth of field unique to the optical element 9 to be used). ) Can be secured.
[0076]
FIG. 2 shows a cross-sectional view of the input / output integrated display 8 and its peripheral portion in the image input apparatus of FIG. 1 in a state where the optical element 9 is installed on the display surface 8a of the input / output integrated display 8. Yes. In FIG. 2, only the surface to be read (document surface) is schematically shown for the document.
[0077]
In this case, the input / output integrated display 8 includes a pair of light-transmitting substrates 8b and 8c made of glass facing each other, the optical sensor 2 sandwiched between the light-transmitting substrates 8b and 8c, and a display (not shown). Elements (liquid crystal layer, EL element, and the like).
[0078]
As the optical element 9 used in the present invention, a lens array such as an erecting equal-magnification lens array, a fiber plate, or the like can be used, but a plurality of erecting equal-magnification lenses 12 as shown in FIG. Is preferably an erecting equal-magnification lens array (a lens array that forms an original image at erecting equal magnification). As the erecting equal-magnification lens array, a SELFOC (registered trademark) lens array or a rod lens array can be used. The SELFOC (registered trademark) lens array is composed of a number of gradient index rod lenses (SELFOC (registered trademark) lenses), and an erecting equal-magnification image of each lens is superimposed to form one continuous image as a whole. An optical system to be formed. In the rod lens array, a large number of rod lenses are arranged in parallel, and erecting equal-magnification images from the respective lenses are superimposed to form one continuous image as a whole.
[0079]
Further, as the erecting equal-magnification lens array (optical element 9), a positive light shielding wall 11 for shielding unnecessary oblique light in the gap between the erecting equal-magnification lens 12 and the erecting equal-magnification lens 12 is formed. It is preferable to use a vertical-magnification lens array (optical element 9). Since the erecting equal-magnification lens array (optical element 9) can relay (image) the image information on the surface of the document 13 to the photosensor formation surface 14, the surface of the document 13 and the photosensor formation surface 14 ( In this case, an image with less blur can be acquired even if the light transmitting substrate 8c far from the document surface 13 is separated from the document side surface. The light shielding wall 11 can be formed of, for example, a low-reflection material such as a two-layer chrome obtained by laminating chromium oxide on a metal chrome, or a resin material in which a black pigment is dispersed in a polymer.
[0080]
In particular, in the case of the input / output integrated display mentioned in the prior art, as shown in FIG. 10, the display is arranged between the surface of the active matrix substrate 101 on which the optical sensor 102 is formed and the screen surface on which the original 103 is closely attached. Since there is a glass substrate and a polarizing plate constituting the panel, the distance L between the surface of the original 103 and the optical sensor 102 inevitably increases, causing a problem of image deterioration such that the read image is blurred. It was. However, in the configuration shown in FIG. 2, information (reading light) on the surface of the document 13 can be relayed (imaged) to the photosensor formation surface 14, so that it is easy to acquire an image with less blur. It becomes possible.
[0081]
Here, the depth of field 15 depends on the opening angle of the erecting equal-magnification lens 12 constituting the optical element 9. For example, in the case of the erecting equal-magnification lens 12 having a small aperture angle, oblique light is significantly cut, so that the depth of field is also greatly increased. As an erecting equal-magnification lens array (optical element 9) having a function of greatly increasing the depth of field, a lens array formed from a gradient index rod lens (Selfoc (registered trademark) lens) ( Selfoc® lens arrays) can be used. Further, an erecting equal-magnification lens array (optical element 9) having a similar function even in a lens array in which a plurality of lens array plates are combined as seen in Japanese Patent Laid-Open No. 2003-139918 (published on May 14, 2003). ) Can be configured.
[0082]
As the input / output integrated display 8, an input / output integrated display including a liquid crystal panel 8d composed of the light transmissive substrates 8b and 8c, the optical sensor 2, a liquid crystal layer, electrodes, driving elements, and the like can be used. In the case of FIG. 2, since an input / output integrated liquid crystal display is used as the input / output integrated display 8, a backlight 16 is provided on the back side (the side far from the original) of the liquid crystal panel 8d. The backlight 16 functions as a backlight light source (transmission display light source) for the liquid crystal panel 8d during display, and as a reference light source (document irradiation light source) for the document surface 13 during image reading.
[0083]
As the input / output integrated display 8, an input / output integrated display including a light emitting element, for example, an EL light emitting element, may be used. Of course, in the case of an input / output integrated display including a light emitting element, the above-described backlight 16 is unnecessary because light from the light emitting element (for example, EL light emission) plays a role of display light or document reference light.
[0084]
In the configuration of the present embodiment, a slide mechanism (horizontal movement mechanism) is provided as switching means for switching the optical element between an installed state and a non-installed state. In the configuration shown in FIG. 1, the side surface (opening portion) of the housing 7 where the input / output integrated display 8 is exposed (two opposing surfaces among the four surfaces surrounding the opening portion; On the two left and right surfaces 10, there are grooves 10 a (shown as lines in FIG. 1, which actually have a width comparable to the thickness of the optical element 9) as a slide mechanism (horizontal movement mechanism). The input / output integrated display 8 is formed along a direction (vertical direction in FIG. 1) substantially parallel to the display surface 8a. Further, the optical element 9 is slid on the groove 10a while being supported by the side surface 10 of the housing 7 by being loosely fitted in the groove 10a (fitted so that the fitted one can move) ( Slide). Thereby, the optical element 9 can slide to the outside of the screen by sliding on the display surface along the groove 10a. That is, the optical element 9 is detachable on the display surface 8a by sliding on the display surface 8a along a direction (vertical direction in FIG. 1) substantially parallel to the display surface 8a of the input / output integrated display 8. That is, it is possible to reciprocate between a position on the display surface 8a and a position outside the screen. The direction in which the optical element 9 slides (slides) is not particularly limited as long as the optical element 9 can move to the outside of the screen.
[0085]
In addition, a rail is provided on the side surface 10 of the portion (opening) where the input / output integrated display 8 is exposed in the housing 7 instead of the groove 10a, and a groove loosely fitted on the rail is provided in the optical element 9, The optical element 9 may be slid along the rail along a direction (vertical direction in FIG. 1) substantially parallel to the display surface 8a of the input / output integrated display 8.
[0086]
As described above, the slide mechanism (groove 10 a) has a mechanism that allows the optical element 9 to slide in a direction parallel to the display surface 8 a of the input / output integrated display 8. Therefore, when a person who operates the image input apparatus wants to observe the display image of the input / output integrated display 8, the optical element 9 is removed from the display surface 8a and placed in a non-installed state, and an image of the document is read (imaging). ), It is possible to use the optical element 9 on the display surface 8a. That is, a person who operates the image input device uses the slide mechanism according to the operation mode (reading or display) of the input / output integrated display 8 to change the state of the optical element 9 (installed state or not installed). State)) can be arbitrarily switched.
[0087]
The user can move the optical element 9 up and down by, for example, providing a vertical movable knob (not shown) connected to the optical element 9 on the side surface of the housing 7 and holding the vertical movable knob by the user. It can be realized by moving up and down. Moreover, you may employ | adopt the method of moving the optical element 9 electrically, etc. instead of a user operating.
[0088]
FIG. 4 is a schematic diagram of an AA ′ cross section of the image input apparatus shown in FIGS. 4A shows an installation state (corresponding to FIG. 1B) in which the optical element 9 is installed on the display surface 8a of the input / output integrated display 8. FIG. The installation state is a form in which an image is read mainly.
[0089]
Inside the casing 7, a gap 3 formed in an opening (a portion of a transparent protective plate 20 described later) of the casing 7 and a gap 4 communicating with the gap 3 are formed. The gap 3 accommodates the input / output integrated display 8 and the optical element 9, and the gap 4 accommodates the optical element 9. Then, as shown in FIG. 4, the optical element 9 enters from the gap 3 on the display surface 8a of the input / output integrated display 8 along a direction substantially parallel to the display surface 8a of the input / output integrated display 8. The output integrated display 8 is movable to the gap 4 that is off the display surface 8a.
[0090]
4B shows a non-installed state (corresponding to FIG. 1A) in which the optical element 9 is retracted from the display surface 8a of the input / output integrated display 8. FIG. In this state, the optical element 9 is built in the gap 4 in the housing 7. In the state where the optical element 9 is retracted from the display surface 8a of the input / output integrated display 8 as shown in FIG. 4B, the display surface 8a of the input / output integrated display 8 is the surface of the image input device main body (housing). It is located in a place that is recessed from (7 surface). The non-installation state is a form in which an image displayed on the input / output integrated display 8 is observed.
[0091]
A groove 10a (or rail) provided on the side surface 10 of the portion (opening) where the input / output integrated display 8 is exposed in the housing 7 is a distance L2 between the optical element 9 and the surface of the display 8. Must be accurately arranged so as to keep the distance at a predetermined distance La. On the other hand, it is necessary to keep the distance L1 between the optical element 9 and the document surface 13 at a predetermined distance Lb. Here, the distance La and the distance Lb are working distances (focal lengths) of the lenses constituting the optical element 9 to be used, and are determined by the performance of the lenses and the like. The distances L1 and L2 are optical distances, and the physical distances are determined by the refractive index of the medium interposed in the middle.
[0092]
Here, in order to maintain the distance L1 between the optical element 9 and the document surface 13 at a predetermined distance La, a transparent spacer (resin plate, glass plate, etc.) having the same optical distance as the distance La is used as the optical element 9. It is preferable to install on top. Further, as shown in FIG. 4A, which will be described later, a transparent protective plate is used as the transparent spacer so that the original can be placed at a position where the distance L1 between the optical element 9 and the original surface 13 matches the predetermined distance La. (Resin plate, glass plate, etc.) 20 is installed, and it is preferable to use the surface of the transparent protective plate 20 as a document installation surface (surface on which the document is brought into close contact). It is preferable that the transparent protective plate 20 is flush with the surface of the casing 7 of the image input apparatus or slightly protrudes from the casing 7 of the image input apparatus so that the original can be brought into close contact therewith. As a result, the user can place the document at a position where the distance L1 becomes the predetermined distance La simply by bringing the document into close contact with the surface of the transparent protective plate 20, which is easy to use.
[0093]
By the way, as described above, the usage method of removing the optical element 9 from the display surface 8a at the time of display has been described as the usage method of the image input apparatus in the present embodiment. However, the optical element 9 can be left on the screen at the time of display. It is possible to use it in such a way. In this case, an observer (user) views the screen through the optical element 9. That is, in actuality, an erect image formed on the viewer side above the optical element 9 is viewed.
[0094]
As a result, light other than the aperture angle of the lens used for the optical element 9 does not reach the observer (user), and the optical element 9 acts as a viewing angle limiting element, placing importance on privacy. This is useful for observers (users).
[0095]
In the image input apparatus shown in FIG. 2 described above, the backlight 16 is provided on the back surface of the display panel 8d in the input / output integrated display 8. However, when the image is read, the light emitted from the backlight 16 is displayed on the display panel. Since the original surface 13 is reached via 8d and the optical element 9, considerable light is lost in the process. For this reason, when the image is read, it is more efficient to install a dedicated document reference light source. FIG. 3 shows a configuration in which a front light (light source) 19 for irradiating a document with light is read between the optical element 9 and the document surface 13 as a document reference light source.
[0096]
The front light 19 is a flat light source designed so that light transmitted through the light guide plate is emitted forward (that is, the document surface 13 side). In this case, the light emitted from the front light 19 can irradiate the document surface 13 with high efficiency without passing through the obstacles such as the display panel and the optical element 9. Therefore, compared to the configuration shown in FIG. 2, the power consumption of the light source at the time of image reading can be greatly reduced.
[0097]
The front light 19 may be fixed so as to be integrated with the optical element 9. Thereby, in conjunction with the state change of the optical element 9, the state of the front light 19 can be arbitrarily switched between the installation state installed on the screen and the non-installation state removed from the screen. it can.
[0098]
Further, light source switching means for switching the front light 19 between an installed state and a non-installed state, for example, a groove formed in the side surface 10 so that the front light 19 can be moved separately from the optical element 9. 10a (or rail) or a driving device for moving the front light 19 may be provided.
[0099]
According to the above configuration, not only the usage method of removing both the optical element 9 and the front light 19 from the screen at the time of display, but also the usage of leaving only the front light 19 off the screen at the time of display and leaving the optical element 9 on the screen. The method can be used. As a result, the observer sees the screen through the optical element 9 (actually, an observer sees an erect image formed on the observer side, which is the upper side of the optical element). As a result, light other than the aperture angle of the lens used for the optical element 9 does not reach the observer, and the optical element 9 acts as a viewing angle limiting element. Useful.
[0100]
In addition, although the form which can perform the operation | movement which switches the optical element 9 between an installation state and a non-installation state by a user's operation was demonstrated here, the image input device of this invention is the optical element 9. An operation of switching between the installed state and the non-installed state may be automatically performed. For example, the mode changeover switch for switching the operation mode (reading or display) of the input / output integrated display 8 and the optical element 9 are moved between the installed state and the non-installed state according to the operation mode of the input / output integrated display 8. And a driving device to be provided. Further, a state change switch for instructing switching of the state (installed state or non-installed state) of the optical element 9 and the optical element 9 are moved between the installed state and the non-installed state in accordance with an instruction from the state change switch. A drive device may be provided.
[0101]
[Embodiment 2]
The following will describe another embodiment of the present invention with reference to FIGS. For convenience of explanation, members having the same functions as those shown in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0102]
FIG. 5A shows an installation state in which an optical element is installed on the display surface of the input / output integrated display in the image input apparatus of this embodiment, and FIG. 5B shows the image input of this embodiment. In the apparatus, a non-installation state in which the optical element is retracted from the display surface of the input / output integrated display is shown.
[0103]
The image input apparatus according to the present embodiment has a more desirable form by adding the following improvements to the image input apparatus according to the first embodiment. That is, in the image input apparatus according to the present embodiment, as shown in FIG. 5, a sensor 31 that detects the position of the optical element 9 is incorporated in a part of the image input apparatus according to the first embodiment. Further, in the image input device of the present embodiment, when the position of the optical element 9 is on the display surface (screen) 8a of the input / output integrated display 8 based on the detection result of the sensor 31 (optical on the display surface 8a). When the element 9 is installed), the operation mode of the input / output integrated display 8 is automatically switched to the reading mode, and conversely, the position of the optical element 9 is not on the display surface 8a of the input / output integrated display 8 ( When the optical element 9 is removed from the display surface 8a), a mode switching unit that automatically switches the operation mode of the input / output integrated display 8 to the display mode is added to the image input device of the first embodiment. .
[0104]
That is, as shown in FIG. 6, the image input apparatus of the present embodiment reads a document image based on the sensor 31 that detects the position of the optical element 9 (see FIG. 5) and the detection result of the sensor 31. A mode switching unit (mode switching unit) 32 that automatically switches between a reading mode and a display mode for displaying an image is provided, and the optical element 9 is linked to change between an installed state and a non-installed state. The mode is switched.
[0105]
The input / output integrated display 8 is not described in the first embodiment, but as shown in FIG. 6, a reading operation unit 33 for reading an image of a document and a display operation unit for displaying an image. 34. The reading operation unit 33 includes a plurality of optical sensors, a signal conversion circuit that converts output signals of these optical sensors into image signals, the front light 19 (or the backlight 16), and the like. The display operation unit 34 includes a driving element (TFT or the like) for driving a pixel such as a liquid crystal cell or an EL element, a driving circuit for driving the driving element based on an image signal, a backlight 16 and the like. The input / output integrated display 8 can be switched between a reading mode in which the reading operation unit 33 is selectively operated and a display mode in which the display operation unit 34 is selectively operated.
[0106]
The mode switching unit 32 of the present embodiment switches to a reading mode in which the reading operation unit 33 is selectively activated when the optical element 9 is in the installed state, and performs a display operation when the optical element 9 is in the non-installed state. The display 34 is switched to a display mode that selectively activates the unit 34.
[0107]
Here, the mode switching unit 32 that switches the mode based on the detection result of the sensor 31 is provided, but the mode switching means is such that the optical element 9 changes between the installed state and the non-installed state. As long as the mode is switched in conjunction with the. For example, when the driving device automatically switches the optical element 9 between the installed state and the non-installed state, mode switching means for switching the mode according to the state of the driving device may be provided. Good.
[0108]
[Embodiment 3]
Still another embodiment of the image input apparatus of the present invention will be described below with reference to FIG. For convenience of explanation, members having the same functions as those in the drawings described in the first and second embodiments are denoted by the same reference numerals and description thereof is omitted.
[0109]
FIG. 7 is a schematic cross-sectional view showing the image input apparatus of this embodiment. As shown in FIG. 7B, the image input device of the present embodiment is provided with a pop-up mechanism (display moving means) 21 for popping up the input / output integrated display 8 to the image input device of the first embodiment. It has a configuration. 7A shows a state where the optical element 9 is installed on the display surface 8a of the input / output integrated display 8 (corresponding to FIG. 1B). This is mainly a form of reading an image.
[0110]
In the image input device according to the first embodiment, the optical element 9 and the optical path length related to the optical element 9 are required to have a thickness of several millimeters, so that the optical element 9 is simply retracted as shown in FIG. Then, the display surface 8a of the input / output integrated display 8 is located in a place that is recessed from the surface of the housing 7 of the image input device, which makes the observer (user) feel uncomfortable.
[0111]
Therefore, in the image input device of this embodiment, as shown in FIG. 7B, when the optical element 9 is retracted, the input / output integrated display 8 is brought closer to the surface of the housing 7 of the image input device. A pop-up mechanism 21 that pops up is provided in a more preferable form. That is, in the image input device of the present embodiment, the input / output integrated display 8 is displayed on the observer's viewpoint (the best display in terms of design) in response to a change in the state of the optical element 9 from the installed state to the non-installed state. A pop-up mechanism 21 is provided that moves so as to approach the (observable position). The pop-up mechanism 21 is preferably one that does not require a power source such as a leaf spring, but may be one that uses a power source.
[0112]
Thereby, it is possible to eliminate the uncomfortable feeling caused by the display surface 8a of the input / output integrated display 8 being located behind the surface of the housing 7 of the image input apparatus.
[0113]
[Embodiment 4]
Still another embodiment of the image input apparatus of the present invention will be described below with reference to FIGS. For convenience of explanation, members having the same functions as those in the drawings described in the first to third embodiments are denoted by the same reference numerals and description thereof is omitted.
[0114]
Here, a foldable image input device is shown as a representative example. 8A and 8B are perspective views showing the image input apparatus according to the present embodiment. FIG. 8A shows a state where the lid is opened, and FIG. 8B shows a state where the lid is closed. 9 is a schematic diagram showing a cross section BB ′ of the image input device shown in FIG. 8, FIG. 9A is a cross-sectional view showing the entire image input device, and FIG. 9B is an image input. It is a fragmentary sectional view which shows a part (part enclosed with the broken line of Fig.9 (a)) of an apparatus.
[0115]
As shown in FIG. 8, the image input apparatus includes a main body 23, a lid 22, and a hinge (switching means, lid switching means) 24 that rotatably connects the lid 22 to one side of the main body 23. ing.
[0116]
The main body 23 of the image input apparatus includes an input / output integrated display 8 in a housing 23a. As the input / output integrated display 8, the same display as that of the first embodiment can be used. The lid 22 includes an optical element 9 for limiting the spread of light of the read image, and transmits light. The hinge 24 supports the lid 22 so as to be rotatable, so that the lid 22 is installed on the display surface 8a (see FIG. 9A) of the input / output integrated display 8 (closed state). And a non-installation state (open state) removed from the display surface 8a.
[0117]
When the lid 22 is opened, the observer (user) can directly observe the image displayed on the input / output integrated display 8. In addition, when the lid 22 is closed, the image input apparatus can read an image of the document through the optical element 9 on the input / output integrated display 8 by bringing the document into close contact with the surface 22A of the lid 22.
[0118]
Here, as a feature of the present embodiment, the present image input apparatus is configured such that the input / output integrated display 8 is provided outside the display surface 8a (that is, the imaging surface; see FIG. 9A) of the input / output integrated display 8. A lid 22 that covers the display surface 8 a is provided, and the optical element 9 is built in the lid 22. Thus, the optical element can be switched between the installed state and the non-installed state by opening and closing the lid 22.
[0119]
The main purpose of providing the optical element 9 is to restrict the light incident on the imaging surface (that is, to limit the oblique incident component) when imaging is performed by the input / output integrated display 8. As a result, even if the document as a subject is a paper having perfect diffusion characteristics, the light passing through the optical element 9 is limited to light within the opening angle of the optical element 9, so that the read image is blurred. Such image degradation can be reduced. That is, it becomes possible to secure a depth of field unique to the optical element 9 to be used.
[0120]
The optical element 9 that can be used is the same as in the first embodiment, and an erecting equal-magnification lens array including a plurality of erecting equal-magnification lenses 12 is preferable as shown in FIG. 9B. Furthermore, it is preferable to use an erecting equal-magnification lens array in which a light shielding wall 11 for shielding unnecessary oblique light is formed in the gap between the erecting equal-magnification lens 12 and the erecting equal-magnification lens 12. Since the erecting equal-magnification lens array can relay the image information on the document surface 13 to the photosensor formation surface 14, there is little blur even if the document surface 13 and the photosensor formation surface 14 are separated from each other. Images can be acquired.
[0121]
Here, the depth of field depends on the aperture angle of the lenses constituting the erecting equal-magnification lens array. For example, in the case of an erecting equal-magnification lens array composed of lenses having a small aperture angle, oblique light is significantly cut, so that the depth of field also increases. Such an erecting equal-magnification lens array can be formed from a gradient index rod lens. Moreover, it is possible to constitute the optical element 9 having the same function even with a lens array in which a plurality of lens array plates are combined.
[0122]
As the input / output integrated display 8, as shown in FIG. 9, a light modulation display panel 8d such as a liquid crystal panel can be used. In this case, the back surface side of the display panel 8d such as a liquid crystal panel ( A backlight 16 is provided on the side far from the original. The backlight 16 serves as a backlight light source for the display panel 8d such as a liquid crystal panel during display, and serves as a reference light source for the document surface 13 during image reading. Of course, when the input / output integrated display 8 includes a light emitting element such as an EL light emitting element, the light from the light emitting element (for example, EL light emission) plays the role of display light or document reference light. Is unnecessary.
[0123]
As shown in FIG. 9A, the lid 22 covering the input / output integrated display 8 includes a housing 22 a having an opening, and the above-described optical element 9 includes the opening of the housing 22 a of the lid 22. Built in. Accordingly, the optical element 9 can be switched between a state where the optical element 9 is installed on the display surface 8a (installation state) and a state where the optical element 9 is removed from the display surface 8a (non-installation state) according to the opening and closing of the lid 22. . Therefore, when a person who operates the image input device wants to observe the display image of the input / output integrated display 8, the lid 22 is opened and the optical element 9 is removed from the display surface 8a (non-installation state). When reading (imaging) a document image, the lid 22 is closed and the optical element 9 is placed on the display surface 8a (installed state). That is, the optical element 9 can be arbitrarily switched between the installed state and the non-installed state according to the operation mode (reading or display) of the input / output integrated display 8.
[0124]
It should be noted that the distance L2 between the optical element 9 and the surface of the input / output integrated display 8 needs to be accurately arranged so as to maintain a predetermined value Lb. On the other hand, also for the distance L1 between the optical element 9 and the document surface 13, it is necessary to ensure a predetermined distance La. Here, the distance La and the distance Lb are the working distance (focal length) of the lens used for the optical element 9, and are determined by the performance of the lens. The distances L1 and L2 are optical distances, and the physical distances are determined by the refractive index of the medium interposed in the middle. Therefore, the thickness of the lid 16 is preferably designed to allow for the distance La and the distance Lb. That is, the thickness of the housing 22 a is set to be thicker than the thickness of the optical element 9 by a thickness corresponding to the focal length of the optical element 9.
[0125]
Therefore, the lid 22 has a transparent protective plate (light transmissive spacer) 20 for setting the distance L1 between the optical element 9 and the document surface 13 to a distance La that matches the focal length of the optical element 9, and an optical element. A transparent protective plate (light transmissive spacer) 20 for setting the distance L2 between the element 9 and the display surface 8a of the input / output integrated display 8 to a distance Lb that matches the focal length of the optical element 9 is provided. It is preferable. In this case, the optical element 9 is sandwiched between the pair of transparent protective plates 20 and 20.
[0126]
That is, when the optical element 9 having the distance L1 between the optical element 9 and the document surface 13 is La, the distance from the surface 22A of the lid 22 (the outer surface of the housing 22a) to the lower side by the distance La, ie, the lid 22 It is preferable to install the optical element 9 so that a step of a distance La is formed between the surface 22A (the outer surface of the housing 22a) and the optical element 9. Then, a transparent protective plate (light transmissive spacer: resin plate, glass plate, etc.) 20 having the same optical distance as the distance La is installed on the surface of the optical element 9 in order to fill the step of the distance La. It is preferable. Conversely, the distance between the rear surface of the lid 22 (the inner surface of the housing 22a) and the distance Lb upward, that is, the distance between the rear surface of the lid 22 (the inner surface of the housing 22a) and the optical element 9. It is preferable to install the optical element 9 so that a step of Lb is formed. Then, a transparent protective plate (light transmissive spacer: resin plate, glass plate, etc.) 20 having the same optical distance as the distance L2 is installed on the back surface of the optical element 9 in order to fill the step of the distance Lb. It is preferable.
[0127]
The transparent protective plate 20 is flush with the surface of the image input device (surface of the housing 22a) or slightly on the surface side of the surface of the image input device (surface of the housing 22a) so that the original can be brought into close contact therewith. A state of protruding outward is preferable. Thus, the user can place the document at a position where the distance L1 from the optical element 9 becomes La simply by bringing the document into close contact with the surface of the transparent protective plate 20, which is easy to use.
[0128]
By the way, it is also possible to use the lid 22 (that is, the optical element 9) so that it can remain on the display surface 8a of the input / output integrated display 8 during display. In this case, the observer views the screen through the optical element 9 (actually, an observer sees an erect image formed on the observer side, which is the upper side of the optical element 9).
[0129]
As a result, light other than the aperture angle of the lens used for the optical element 9 does not reach the observer, and the optical element 9 acts as a viewing angle limiting element. Useful.
[0130]
Also in the present embodiment, as in the second embodiment, a sensor for detecting the position of the lid 22 is built in a part of the image input device, and the lid 22 is installed on the display surface 8a (closed). State), the operation mode of the input / output integrated display 8 is automatically switched to the reading mode. Conversely, when the lid 22 is removed from the display surface 8a (open state), the input / output integrated type is displayed. It is desirable to provide a mode switching unit that automatically switches the operation mode of the display 8 to the display mode.
[0131]
In the image input device shown in FIGS. 8 and 9 described above, the backlight 16 is provided on the back surface of the display panel 8d. In this process, a considerable amount of light is lost. For this reason, when the image is read, it is more efficient to install a dedicated document reference light source. Therefore, as shown in FIG. 3 of the first embodiment, a configuration in which a front light 19 is installed between the optical element 9 and the document surface 13 may be adopted as the document reference light source. The front light 19 is designed so that light transmitted through the light guide plate is emitted forward (that is, on the document surface side). In this case, the light emitted from the front light 19 can irradiate the document surface 13 with high efficiency without passing through the obstacles such as the display panel 8 and the optical element 9. For this reason, compared with the image input apparatus shown in FIGS. 8 and 9, it is possible to significantly reduce the power consumption of the light source during image reading. The front light 19 can be incorporated in a transparent protective plate (light transmissive spacer) 20 that fills the distance L1 in FIG.
[0132]
Although the example in which the lid 22 rotates is described here, the lid 22 may be slid in a direction substantially parallel to the display surface 8a of the input / output integrated display 8 as in the first embodiment. Good. Although the embodiment has been described here in which the lid 22 can be opened and closed by a user's operation, the lid 22 may be opened and closed by a driving device.
[0133]
[Embodiment 5]
In the above-described first to fourth embodiments, the input / output integrated display (panel) 8 and the optical element 9 that is provided on the display and can be arbitrarily switched between the installed state and the non-installed state are provided. Although the image input apparatus has been described, such an image input apparatus can be applied as follows.
[0134]
The purpose of installing the optical element 9 on the display surface 8a of the input / output integrated display 8 when reading an image is to improve the depth of field at the time of reading. On the other hand, the effect of improving the depth of field associated with the installation of the optical element 9 involves a trade-off of light utilization efficiency. For example, the light utilization efficiency (light transmission rate) of a typical erecting equal-magnification lens array is about 1 to 5%.
[0135]
Therefore, when it is important to increase the depth of field at the time of image reading, the optical element 9 is installed on the display surface 8 a of the input / output integrated display 8. And about the fall of the light utilization efficiency resulting from installation of the optical element 9, it is good to make a reading time long and to make up with time integration.
[0136]
On the other hand, when the depth of field at the time of image reading is not emphasized, the optical element 9 on the display surface 8a of the input / output integrated display 8 is set in a non-installed state. Since the use efficiency is good as much as the optical element 9 is not used, it is preferable to read at high speed.
[0137]
The image input apparatus of this embodiment includes an input / output integrated display 8 capable of reading an image, and an optical element 9 that allows a user to arbitrarily switch between installation and non-installation on the input / output integrated display 8. A state (A) in which the optical element 9 is installed on the input / output integrated display 8 and a state (B) in which the optical element 9 is not installed on the input / output integrated display 8 However, the image can be read, and the depth of field at the time of image reading is larger in the form (A) than in the form (B), while the image reading speed is higher than that in the form (A). Thus, the mode (B) is faster.
[0138]
That is, the image input apparatus according to the present embodiment is provided with an input / output integrated display (area sensor) 8 capable of reading an image of a document on the display surface (surface) 8a and the display surface 8a. In addition, the optical element that increases the depth of field at the time of image reading compared to the case where it is removed from the display surface 8a, the installation state in which the optical element 9 is installed on the display surface 8a, and the above Switching means for switching between a non-installation state removed from the display surface 8a, for example, a groove 10a, and a reading speed control means for changing an image reading speed, the reading speed control means includes an image reading speed. Is changed so that the non-installation state is faster than the installation state.
[0139]
Accordingly, it is possible to realize an image input device that allows the user to switch the depth of field, the reading speed, and the (use form) according to whether the depth of field or the reading speed is important. it can.
[0140]
Such proper use of the reading mode is not limited to the combination of the input / output integrated display and the optical element, but can be widely applied to all input-only image reading panels (that is, read-only area sensors). .
[0141]
In the first to fifth embodiments described above, an image input including the input / output integrated display 8 or the read-only area sensor and the optical element 9 provided on the display and capable of arbitrarily switching between installation and non-installation. The apparatus has been described. However, the installation form of the optical element 9 on the input / output integrated display 8 or the read-only area sensor is not limited to this, and the optical element 9 can be switched between the installation state and the non-installation state. If so, the object of the present application is achieved. For example, the input / output integrated display 8 or the read-only area sensor and the optical element 9 are not completely integrated without being integrated, and the optical element 9 is connected to the input / output integrated display 8 or the read-only display only when necessary. An attachment mechanism (switching means) that can be attached to the area sensor may be provided.
[0142]
Furthermore, the present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and can be obtained by appropriately combining technical means disclosed in different embodiments. Embodiments are also included in the technical scope of the present invention.
[0143]
【The invention's effect】
As described above, the image input apparatus according to the present invention limits the spread of light in the read image, and the input / output integrated display that can display the image and read the image of the subject on the same screen. And a switching means for switching the optical element between an installation state installed on the screen and a non-installation state removed from the screen.
[0144]
Therefore, the display performance is not impaired by the optical element while the blur of the image when reading the image is improved and the image is displayed. That is, the present invention has an effect that an input / output integrated image input apparatus capable of achieving both image reading performance and display performance can be provided.
[0145]
As described above, the image input device of the present invention has an area sensor that can read an image of a document on a surface, and a case where the image input device is installed on the surface, compared to a case where the image input device is removed from the surface. An optical element for increasing the depth of field at the time of image reading; and a switching means for switching the optical element between an installation state installed on the surface and a non-installation state removed from the surface; A reading speed control means for changing the image reading speed, and the reading speed control means is configured to change the image reading speed so that the non-installation state is faster than the installation state. .
[0146]
Accordingly, it is possible to provide an image input device that can selectively use a mode in which a read image without blur is obtained and a mode in which an image can be read at high speed.
[Brief description of the drawings]
1A and 1B are diagrams showing an image input device according to an embodiment of the present invention, wherein FIG. 1A is a diagram showing the image input device when an optical element is not installed, and FIG. FIG. 3 is a diagram illustrating the image input device in which an optical element is in an installed state.
FIG. 2 is a cross-sectional view of the input / output integrated display portion in FIG. 1 when an optical element is installed.
FIG. 3 is a cross-sectional view of an input / output integrated display portion provided with a front light as a document reference light source.
4 is a schematic diagram of an AA ′ cross section of the image input apparatus shown in FIG. 1, (a) is a diagram showing a state in which an optical element is installed on a screen, and (b) is a diagram showing the optical element. It is a figure which shows the state evacuated from on the screen.
5A and 5B are cross-sectional views of an image input apparatus according to another embodiment of the present invention, in which FIG. 5A is a diagram illustrating a state in which an optical element is installed on a screen, and FIG. It is a figure which shows the state evacuated from the top.
6 is a block diagram showing a configuration of the image input apparatus shown in FIG. 5. FIG.
7A is a cross-sectional view of an image input apparatus according to still another embodiment of the present invention, and FIG. 7A is a diagram showing a state where an optical element is installed on a screen, and FIG. It is a figure which shows the state evacuated from on the screen.
FIG. 8 is a perspective view showing a foldable image input device as another embodiment of the present invention, and (a) is a diagram showing the image input device when the optical element is not installed; b) is a diagram showing an image input device when an optical element is in an installed state.
9A and 9B are schematic views showing a BB ′ cross section of the image input apparatus shown in FIG. 8, where FIG. 9A is a cross-sectional view showing the whole, and FIG. 9B is a partial cross-sectional view.
FIG. 10 is a diagram showing an input / output integrated type liquid crystal display in which an active matrix substrate includes a TFT element and a photosensor element. FIG. 10A shows a case where the distance between the document and the photosensor board is short, and FIG. The case where the distance between the document and the optical sensor substrate is separated is shown.
[Explanation of symbols]
7 Case
8 Input / output integrated display (area sensor)
8a Display surface (screen)
8d display panel
9 Optical elements
10a Groove (switching means, slide mechanism)
11 Shading wall
12 Erect life-size lens (lens)
13 Original side
16 Backlight
19 Front light (light source)
20 Transparent protective plate (light transmissive spacer)
21 Pop-up mechanism (display moving means)
22 Lid
22a housing
24 Hinge (switching means, lid switching means)
31 sensors
32 Mode switching unit (mode switching means)
33 Reading operation part
34 Display operation part

Claims (14)

An input / output integrated display that can perform image display and subject image reading on the same screen;
An optical element for limiting the spread of light in the read image;
An image input apparatus comprising: switching means for switching the optical element between an installation state installed on the screen and a non-installation state removed from the screen. The image input apparatus according to claim 1, wherein the optical element is an erecting equal-magnification lens array including a plurality of lenses. A light source for irradiating the document with light when reading the image;
The image input device according to claim 1, wherein the light source is fixed so as to be integrated with the optical element. A light source for illuminating the document when reading the image;
The image input according to claim 1, further comprising: a light source switching unit that switches the light source between an installation state installed on the screen and a non-installation state removed from the screen. apparatus. Mode switching means for switching between a reading mode for reading an image of a document and a display mode for displaying an image;
2. The image according to claim 1, wherein the mode switching unit performs mode switching in conjunction with a change in the optical element between an installed state and a non-installed state. Input device. The switching means is
2. The image according to claim 1, further comprising a slide mechanism that supports the optical element so that the optical element can slide on the screen and reciprocate between a position on the screen and a position outside the screen. Input device. The image according to claim 1, further comprising display moving means for moving the display so as to approach the observer's viewpoint in response to a change in state of the optical element from an installation state to a non-installation state. Input device. A lid for covering the screen;
The optical element is built in the lid,
The said switching means is a lid switching means which switches the said lid | cover between the installation state installed on the said screen, and the non-installation state removed from the said screen. Image input device. The optical element is provided in the opening of the housing,
9. A light transmissive spacer is installed on the optical element so that a lid surface of a portion where the optical element is installed is substantially flush with a surface of the housing. The image input device described in 1. The optical element is provided in the opening of the housing,
9. The image input apparatus according to claim 8, wherein the thickness of the casing is set to be thicker than the thickness of the optical element by a thickness corresponding to the focal length of the optical element. An area sensor that can read a document image on the surface,
An optical element that increases the depth of field at the time of image reading when installed on the surface as compared to when removed from the surface;
Switching means for switching the optical element between an installation state installed on the surface and a non-installation state removed from the surface;
A reading speed control means for changing the reading speed of the image,
The image input apparatus, wherein the reading speed control means changes an image reading speed so that the non-installation state is faster than the installation state. 12. The image input device according to claim 11, wherein the area sensor is an input / output integrated display capable of displaying an image and reading an image of a document on the same screen. The image input apparatus according to claim 11, wherein the optical element is an erecting equal-magnification lens array including a plurality of lenses. The image input apparatus according to claim 2, further comprising a light shielding wall formed in a gap between the lenses constituting the erecting equal-magnification lens array.

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